Programmable light beam shape altering device using separate programmable micromirrors for each primary color

ABSTRACT

Three-digital micromirror devices (“DMD”) are used to alter the shape of light that is projected onto a stage. The DMDs each receive a primary color and selectively reflects some light of that color, thereby shaping the light that is projected onto the stage. The control for the alteration is controlled by an image. That image can be processed, thereby carrying out image processing effects on the shape of the light that is displayed. One preferred application follows the shape of the performer and illuminates the performer using a shape that adaptively follows the performer&#39;s image. This results in a shadowless follow spot.

The present application claims priority from provisional application No. 60/109,576, filed Nov. 23, 1998.

FIELD OF THE INVENTION

The present invention relates to a programmable light beam shaping device. More specifically, the present invention teaches a control system and three micromirror devices which can alter the shape and color of light beams passing therethrough, and also provide various effects to those shaped light beams using image processing circuitry that is provided in the remote luminaire.

BACKGROUND OF THE INVENTION

It is known in the art to shape a light beam. This has typically been done using an element known as a gobo. A gobo element is usually embodied as either a shutter or an etched mask. The gobo shapes the light beam like a stencil in the projected light.

Analog gobos are simple on/off devices: they allow part of the light beam to pass, and block other parts to prevent those other parts from passing. Hence mechanical gobos are very simple devices. Modern laser-etched gobos go a step further by providing a gray scale effect.

Typically multiple different gobo shapes are obtained by placing the gobos are placed into a cassette or the like which is rotated to select between the different gobos. The gobos themselves can also be rotated within the cassette, using the techniques, for example, described in U.S. Pat. Nos. 5,113,332 and 4,891,738.

All of these techniques have the drawback that only a limited number of gobo shapes can be provided. These gobo shapes must be defined in advance. There is no capability to provide any kind of gray scale in the system. The resolution of the system is also limited by the resolution of the machining. This system allows no way to switch gradually between different gobo shapes. In addition, moving between one gobo and another is limited by the maximum possible mechanical motion speed of the gobo-moving element.

Various patents and literature have suggested using a liquid crystal as a gobo. For example, U.S. Pat. No. 5,282,121 describes such a liquid crystal device. Our own pending patent application also so suggests. However, no practical liquid crystal element of this type has ever been developed. The extremely high temperatures caused by blocking some of this high intensity beam produce enormous amounts of heat. The projection gate sometimes must block beams with intensities in excess of 10,000 lumens and sometimes as high as 2000 watts. The above-discussed patent applications discuss various techniques of heat handling. However, because the light energy is passed through a liquid crystal array, some of the energy must inevitably be stored by the liquid crystal. Liquid crystal is not inherently capable of storing such heat, and the phases of the liquid crystal, in practice, may be destabilized by such heat. The amount of cooling required, therefore, has made this an impractical task. Research continues on how to accomplish this task more practically.

It is an object of the present invention to obviate this problem by providing a digital light beam shape altering device, e.g. a gobo, which operates completely differently than any previous device. Specifically, this device embodies the inventor's understanding that many of the heat problems in such a system are obviated if the light beam shape altering device would selectively deflect, instead of blocking, the undesired light.

The preferred mode of the present invention uses a digitally-controlled micromirror semiconductor device. However, any selectively-controllable multiple-reflecting element could be used for this purpose. These special optics are used to create the desired image using an array of small-sized mirrors which are movably positioned. The micromirrors are arranged in an array that will define the eventual image. The resolution of the image is limited by the size of the micromirrors: here 17 μm on a side.

The mirrors are movable between a first position in which the light is directed onto the field of a projection lens system, or a second position in which the light is deflected away from the projection lens system. The light deflected away from the lens will appear as a dark point in the resulting image on the illuminated object. The heat problem is minimized according to the present invention since the micromirrors reflect the unwanted light rather than absorbing it. The absorbed heat is caused by the quantum imperfections of the mirror and any gaps between the mirrors.

SUMMARY

The disclosed mode uses a light splitting element to split the light into its primary colors, preferably red, green, and blue, or cyan, magenta, yellow. Each of the primary colors are coupled to a separate digital micromirror device. Each device reflects only desired pixels of the light representing the primary colors. Hence, this operates to form shaped beams of colored lights in any desired colors, to be projected. The primary colors are then re-combined and projected.

Since there is no separate color altering element in the path of the device, the light output from the device can be less attenuated than the prior art.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other objects will be readily understood with reference to the accompanying drawings, in which:

FIG. 1 shows a single pixel mirror element of the preferred mode, in its first position;

FIG. 2 shows the mirror element in its second position;

FIG. 3 shows the mirror assembly of the present invention and its associated optics;

FIG. 4 shows more detail about the reflection carried out by the DMD of the present invention;

FIG. 5 shows a block diagram of the control electronics of the present invention;

FIG. 6 shows a flowchart of a typical operation of the present invention;

FIG. 7 shows a flowchart of operation of edge effects operations;

FIG. 8A shows a flowchart of a first technique of following a performer on stage;

FIG. 8B shows a flowchart of a correlation scheme;

FIG. 8C shows a flowchart of another correlation scheme; and

FIG. 9 shows a block diagram of the shadowless follow spot embodiment.

DESCRIPTION OF THE PREFERRED EMBODIMENT

The preferred embodiment herein begins with a brief description of controllable mirror devices, and the way in which the currently-manufactured devices operate.

Work on semiconductor-based devices which tune the characteristics of light passing therethrough has been ongoing since the 1970's. There are two kinds of known digital micromirror devices. A first type was originally called the formal membrane display. This first type used a silicon membrane that was covered with a metalized polymer membrane. The metalized polymer membrane operated as a mirror.

A capacitor or other element was located below the metalized element. When the capacitor was energized, it attracted the polymer membrane and changed the direction of the resulting reflection.

More modern elements, however, use an electrostatically deflected mirror which changes in position in a different way. The mirror of the present invention, developed and available from Texas Instruments, Inc. uses an aluminum mirror which is sputter-deposited directly onto a wafer.

The individual mirrors are shown in FIG. 1. Each individual mirror includes a square mirror plate 100 formed of reflective aluminum cantilevered on hollow aluminum post 102 on flexible aluminum beams. Each of these mirrors 100 have two stop positions: a landing electrode, which allows them to arrive into a first position shown in FIG. 2, and another electrode against which the mirror rests when in its non-deflected position. These mirrors are digital devices in the sense that there two “allowable” positions are either in a first position which reflects light to the lens and hence to the illuminated object, and a second position where the light is reflected to a scattered position. Light scattering (i.e. selective light reflection) of this type could also be done with other means, i.e. selectively polarizable polymers, electronically-controlled holograms, light valves, or any other means.

The operation of the dark field projection optics which is used according to the preferred micromirror device is shown in FIG. 3. The two bi-stable positions of the preferred devices are preferably plus or minus 10% from the horizontal.

The light is produced by a lamp 300, with a reflector 302. Light is coupled through a heat rejection device, e.g., a cold mirror 303 which rejects at least some of the heat. The heat rejection device could be located in other areas, e.g. after the optical components described below.

That light is input to a color splitting device 310 which splits the color into its three primary colors, e.g., red, green, and blue. Color splitting device 310 is shown as a prism, although other color splitting devices could be used. Each primary color is detracted in a different direction, and each primary color is respectively input to its own DMD device 320, 321, and 319. Each DMD device operates to either tilt the light in the desired direction shown as 325 or in the undesired direction shown 335. The desired direction tilts the light 325 towards a combining device 329. The combining device 329 combines the images produced by the three DMDs, 319, 320, 321 into a single beam of light 327 which is input to a field lens 330, 332.

Light source 310 used according to the present invention is preferably a high intensity light source such as a xenon or metal halide bulb of between 600 and 1000 watts. The bulb is preferably surrounded by a reflector of the parabolic or ellipsoidal type which directs the output from bulb 300 along a first optical incidence path 305.

However, the lighting system 310 can actually have less power than in previous systems, since no separate color changing device needs to be used, and each pass through a color changing device reduces the intensity of the light.

The light intensity may also be controlled using any kind of associated dimmer; either electronic, mechanical or electromechanical means. More preferably, the DMD 320 could be used to control beam intensity as described herein.

The light beam projected 310 along path 305 is incident to the digital light altering device embodied as DMD 320, at point 322. The DMD allows operations between two different states. When the mirror in the DMD is pointed to the right, the right beam is reflected along path 325 to projection/zoom lens combination 330, 332. The zoom lens combination 330, 332 is used to project the image from the DMD 320 onto the object of illumination, preferably a stage. The size and sharpness quality of the image can therefore be adjusted by repositioning of the lens. When the mirror is tilted to the right, the light beam is projected along the light path 335, away from projection lens 330/332. The pixels which have light beams projected away from the lens appear as dark points in the resulting image. The dark spots are not displayed on the stage.

This DMD system reflects information from all pixels. Hence, minimal energy is absorbed in the DMD itself or any of the other optics. The device still may get hot, however not nearly as hot as the liquid crystal gobos. Cooling 325 is still necessary. The DMDs can be cooled using any of the techniques described in our copending applications, or by a heat sink and convection, or by blowing cold air from a refrigeration unit across the device. More preferably, a hot or cool mirror can be used in the path of the light beam to reflect infrared out of the light beam to minimize the transmitted heat. FIG. 3 shows hot mirror 330 reflecting infra red 332 to heat sink 334. A cold mirror could be used with a folded optical path. Each of the other DMDs 319, 321, operates in a similar way.

This basic system allows selecting a particular aperture shape with which to which pass the light. That shape is then defined in terms of pixels, and these pixels are mapped to DMD 320. The DMD selectively reflects light of the properly-shaped aperture onto the stage. The rest of the light is reflected away.

The micromirror can be switched between its positions in approximately 10 μs. A normal time for frame refresh rate, which takes into account human persistence of vision, is {fraction (1/60)}th of a second or 60 hertz. Various effects can be carried out by modulating the intensity of each mirror pixel within that time frame.

The monolithic integration which is being formed by Texas Instruments includes associated row and column decoders thereon. Accordingly, the system of the present invention need not include those as part of its control system.

Detailed operation of DMDs 319, 321 is shown in FIG. 4. The source beam is input to the position 322 which transmits the information either towards the stage along path 325 or away from the stage along path 335.

The various effects which are usable according to the present invention include automatic intensity dimming, use of a “shadowless follow spot”, hard or soft beam edges, shutter cut simulation, gobo cross fading, gobo special effects, stroboscopic effects, color gobos, rotating gobos including absolute position and velocity control, and other such effects and combinations thereof. All of these effects can be controlled by software running on the processor device. Importantly, the characteristics of the projected beam (gobo shape, color etc) can be controlled by software. This enables any software effect which could be done to any image of any image format to be done to the light beam. The software that is used is preferably image processing software such as Adobe photoshop™ Kai's power tools™, Adobe Streamline, or the like which are used to manipulate images. Any kind of image manipulation can be mapped to the screen. Each incremental changes to the image can be mapped to the screen as it occurs.

Another important feature of the gobo is its ability to project unconnected shapes that cannot be formed by a stencil. An example is two concentric circles. A concentric circle gobo needs physical connection between the circles. Other unconnected shapes which are capable of rendering as an image can also be displayed.

The effects carried out by the software are grouped into three different categories: an edge effects processing; an image shape processing; and a duty cycle processing.

The overall control system is shown in block diagram form in FIG. 5. Microprocessor 500 operates based on a program which executes, inter alia, the flowchart of FIG. 6. The light shape altering operates according to a stencil outline. This stencil outline can be any image or image portion. An image from image source 552 is input to a format converter 552 which converts the image from its native form into digital image that is compatible with storage on a computer. The preferred digital image formats include a bitmap format or compressed bitmap form such as the GIF, JPEG, PCX format (1 bit per pixel) file, a “BMP” file (8 bits/pixel B/W or 24 bits/pixel color) or a geometric description (vectorized image). Moving images could also be sent in any animation format such as MPEG or the like. It should be understood that any image representation format could be used to represent the image, and that any of these representations can be used to create information that can modify reflecting positions of the array of reflecting devices. The present specification uses the term “digital representation” to generically refer to any of these formats that can be used to represent an image, and are manipulable by computers.

In this mode, the saved signal can be a control signal indicative of shape and color, e.g. one that defines both chrominance and luminance. That same signal can be applied to all the DMDs, and each responds to its own color portion. Another way produces separate signals for each of the primary colors, and applies those signals to the DMDs.

Image 554 is input into a working memory 556. BMP format represents each “pixel” picture element of the image by a number of bits. A typical gray scale bit map image has 8 bits representing each pixel. A colored image of this type has 8 bits representing each of red, green, and blue representations. This color representation is called a 24-bit representation, since 24-bits are necessary for each pixel. The description herein will be given with reference to gray scale images although it should be understood that this system can also be used with color images by forming more detailed maps of the information. Bit maps are easiest to process, but extremely wasteful of storage space.

Each memory area, representing each pixel, therefore, has 8 bits therein. The memory 556 is 576×768 area, corresponding to the number of mirror elements in the preferred use.

This image is defined as image No. x, and can be stored in non-volatile memory 520 (e.g., flash RAM or hard disk) for later recall therefrom. An important feature of the present invention is that the images are stored electronically, and hence these images can also be electronically processed in real time using image processing software. Since the preferred mode of the present invention manipulates the image information in bitmap form, this image processing can be carried out in a very quick succession.

The image to be projected is sent, by processor 500, over channel 560, to VRAM 570. Line driver 562 and line receiver 564 buffer the signal at both ends. The channel can be a local bus inside the lamp unit, or can be a transmission line, such as a serial bus. The image information can be sent in any of the forms described above.

Standard and commonly available image processing software is available to carry out many functions described herein. These include for example, morphing, rotating, scaling, edge blurring, and other operations that are described herein. Commercial image processing can use “Kai's Power Tools”, “CorelDraw!”, or “Morph Studio” for example. These functions are shown with reference to the flowchart of FIG. 6.

Step 600 represents the system determining the kind of operation which has been requested: between edge processing, image processing, and duty cycle processing. The image processing operations will be defined first. Briefly stated, the image processing operations include rotation of the image, image morphing from image 1 to image 2, dynamic control of image shape and special effects. Each of these processing elements can select the speed of the processing to effectively time-slice the image. The morphing of the present invention preferably synchronizes keyframes of the morph with desired time slices.

Step 602 defines the operation. As described above, this operation can include rotation, position shift, and the like. Step 604 defines the time or velocity of operation. This time can be ending time for all or part of the movement, or velocity of the movement. Note that all of the effects carried out in step 602 require moving some part of the image from one position to another.

Step 606 determine the interval of slicing, depending on the velocity. It is desirable to slice an appropriate amount such that the user does not see jerky motion. Ideally, in fact, we could slice movement of the image one pixel at a time, but this is probably unnecessary for most applications. One hundred pixel slicing is probably sufficient for all applications. The pixel slices are selected at step 606.

Step 608 calculates using the time or velocity entered at step 604 to determine the necessary time for operation based on the amount of position shift for rotation over 100 pixel slices. This is done as follows. Position shift, rotate, and sprite animation are all simple movements. In both, the points of the image which define the gobo shape move over time. It is important, therefore, to decide how much movement there is and how much time that movement will take. A rate of change of points or velocity is then calculated. Of course velocity need not be calculated if it has already been entered at step 604.

Having velocity of movement and pixels per second, the time between slices is calculated using 100 pixels per slice divided by the velocity in pixels per second. The direction of movement is defined by this operation.

Therefore, the red, green, and blue components of the image is recalculated at step 610 for each time interval. These new image becomes the new gobo stencil and colors at the new location. That is to say, the outline of the image is preferably used as the gobo—light within the image is passed in the desired color, and light outside the image is blocked. At any particular time, the image in the VRAM 570 is used as the gobo stencil.

A pixel value of 1 indicates that light at the position of the pixel will be shown on the stage. A pixel value of zero indicates that light at the position of the pixel will not be shown on the stage. Any gray scale value means that only part of the intensity pixel will be shown (for only part of the time of the {fraction (1/60)}th of a second time slice). Hence, each element in the memory is applied to one pixel of the DMD, e.g. one or many micromirrors, to display that one pixel on the stage.

When edge processing is selected at step 600, control passes to the flowchart of FIG. 7. The edge graying can be selected as either a gradual edge graying or a more abrupt edge graying. This includes one area of total light, one area of only partial light, and one area of no light. The intensity of the gray scaled outline is continuously graded from full image transmission to no image transmission. The intensity variation is effected by adjusting the duty cycle of the on and off times.

Step 700 obtains the image and defines its outlines. This is carried out according to the present invention by determining the boundary point between light transmitting portions (1's) and light blocking portions (0's). The outline is stretched in all directions at step 702 to form a larger but concentric image—a stretched image.

The area between the original image and the stretched image is filled with desired gray scale information. Step 704 carries this out for all points which are between the outline and the stretch image.

This new image is sent to memory 570 at step 706. As described above, the image in the memory is always used to project the image-shaped information. This uses standard display technology whereby the display system is continually updated using data stored in the memory.

The duty cycle processing in the flowchart of FIG. 6 is used to form strobe effects and/or to adjust intensity. In both cases, the image is stored in memory and removed from memory at periodic intervals. This operation prevents any light from being projected toward the stage at those intervals, and is hence referred to as masking. When the image is masked, all values in the memory become zero, and hence this projects all black toward the source. This is done for a time which is shorter than persistence of vision, so the information cannot be perceived by the human eye. Persistence of vision averages the total light impinging on the scene. The eye hence sees the duty cycle processing as a different intensity.

The stroboscopic effect turns on and off the intensity, ranging from about 1 Hz to 24 Hz. This produces a strobe effect.

These and other image processing operations can be carried out: (1) in each projection lamp based on a prestored or downloaded command; (2) in a main processing console; or (3) in both.

Another important aspect of the invention is based on the inventor's recognition of a problem that has existed in the art of stage lighting. Specifically, when a performer is on the stage, a spotlight illuminates the performer's area. However, the inventor of the present invention recognized a problem in doing this. Specifically, since we want to see the performer, we must illuminate the performer's area. However, when we illuminate outside the performer's area, it casts a shadow on the stage behind the performer. In many circumstances, this shadow is undesirable.

It is an object of this embodiment to illuminate an area of the stage confined to the performer, without illuminating any location outside of the performer's area. This is accomplished according to the present invention by advantageous processing structure which forms a “shadowless follow spot”. This is done using the basic block diagram of FIG. 9.

The preferred hardware is shown in FIG. 9. Processor 1020 carries out the operations explained with reference to the following flowcharts which define different ways of following the performer. In all of these embodiments, the shape of the performer on the stage is determined. This can be done by (1) determining the performer's shape by some means, e.g. manual, and following that shape; (2) correlating over the image looking for a human body shape; (3) infra red detection of the performer's location followed by expanding that location to the shape of the performer; (4) image subtraction; (5) detection of special indices on the performer, e.g. an ultrasonic beacon, or, any other technique even manual following of the image by, for example, an operator following the performer's location on a screen using a mouse.

FIG. 8A shows a flowchart of (1) above. At step 8001, the performer is located within the image. The camera taking the image is preferably located at the lamp illuminating the scene in order to avoid parallax. The image can be manually investigated at each lamp or downloaded to some central processor for this purpose.

Once identified, the borders of the performer are found at 8005. Those borders are identified, for example, by abrupt color changes near the identified point. At step 8010, those changes are used to define a “stencil” outline that is slightly smaller than the performer at 8010. That stencil outline is used as a gobo for the light at 8015.

The performer continues to move, and at 8020 the processor follows the changing border shape. The changing border shape produces a new outline which is fed to 8010 at which time a new gobo stencil is defined.

Alternative (2) described above is a correlation technique. A flowchart of this operation is shown in FIG. 8B. At step 8101, the camera obtains an image of the performer, and the performer is identified within that image. That image issued as a kernel for further later correlation. The entire scene is obtained at step 8105. The whole scene is correlated against the kernel at 8110. This uses known image processing techniques.

The above can be improved by (3), wherein infra red detection gives the approximate area for the performer.

As explained in previous embodiments, the DMD is capable of updating its position very often: for example, 10⁶ times a second. This is much faster than any real world image can move. Thirty times a second would certainly be sufficient to image the performer's movements. Accordingly, the present invention allows setting the number of frame updates per second. A frame update time of 30 per second is sufficient for most applications. This minimizes the load on the processor, and enables less expensive image processing equipment to be used.

FIG. 8C shows the image subtracting technique.

First, we must obtain a zeroing image. Therefore, the first step at step 800, is to obtain an image of the stage without the performer(s) thereon. This zero image represents what the stage will look like when the performers are not there.

Between processing iterations, the processor can carry out other housekeeping tasks or can simply remain idle.

Step 802 represents the beginning of a frame update. An image is acquired from the video camera 550 at step 804. The image is still preferably arranged in units of pixels, with each pixel including a value of intensity and perhaps red, green, and blue for that pixel.

At step 806 subtracts the current image from the zeroed image. The performer image that remains is the image of the performer(s) and other new elements on the stage only. The computer determines at this time which part of that image we want to use to obtain the shadowless follow spot. This is done at step 808 by correlating the image that remains against a reference, to determine the proper part of the image to be converted into a shadowless follow spot. The image of the performer is separated from other things in the image. Preferably it is known for example what the performer will wear, or some image of a unique characteristic of the performer has been made. That unique characteristic is correlated against the performer image to determine the performer only at the output of step 808. This image is digitized at step 810: that is all parts of this image which are not performer are set to zeros so that light at those positions is reflected. In this way, a gobo-like image is obtained at step 810, that gobo-like image being a changing cutout image of the performer. An optional step 812 further processes this image to remove artifacts, and preferably to shrink the image slightly so that it does not come too close to the edge of the performer's outline. This image is then transferred to the VRAM at step 814, at which time it is re-entered into the DMD 1012 to form a gobo-like mask for the lamp. This allows the light to be appropriately shaped to agree with the outline of the performer 1004.

Another embodiment of the present invention uses the above described techniques and basic system of the present invention to provide color to the lamp gobo. This is done using techniques that were postulated in the early days of color tv, and which now find a renewed use. This system allows colored gobos, and more generally, allows -any video image to be displayed.

Further details of this system are found in copending application Ser. Nos. 08/854,353, 09/029,224, 09/108,263, and 09/145,314, the disclosures of which are incorporated by reference.

Although only a few embodiments have been described in detail above, those having ordinary skill in the art will certainly understand that many modifications are possible in the preferred embodiment without departing from the teachings thereof.

All such modifications are intended to be encompassed within the following claims.

For example, any direction deflecting device could be used in place of the DMD, e.g., a grating light valve, which still constitute digital light altering devices.

A custom micro mirror device would be transparent, and have thin mirrors that “stowed” at 90° to the light beam to allow the beam to pass, and turned off by moving to a reflecting position to scatter select pixels of the light beam.

The three color approach could also be carried out by using three primary light sources, one for each color, instead of splitting the light from a single source. 

What is claimed is:
 1. A light shape altering device, having elements which selectively modify light, located in the path of a light beam and comprising: a controller which obtains a desired shape for a colored beam of light, and converts said shape into control signals indicative of color components of both said desired shape and colors; a first controllable light reflection device, receiving at least part of said control signal, having a plurality of controllable elements, each element defining a portion of an image, and each element being separately controllable between a first state which passes light to a desired object of illumination and a second state which reflects light away from the desired object of illumination; and a second controllable light reflection device, receiving at least part of said control signal, having a plurality of controllable elements, each element defining a portion of an image, and each element being separately controllable between a first state which passes light to a desired object of illumination and a second state which reflects light away from the desired object of illumination.
 2. A device as in claim 1, wherein said light reflection devices are digital mirror devices.
 3. A device as in claim 1, wherein said controller produces multiple signals, one of which is applied to said first light reflection device, and a second of which is applied to said second light reflection device.
 4. A device as in claim 1, further comprising a third light reflection device.
 5. A device as in claim 1, wherein said first, second and third light reflection devices respectively are controlled for red, green and blue components of the signal.
 6. A device as in claim 1, wherein said first, second and third light reflection devices respectively are controlled for cyan, magenta, yellow components of the signal.
 7. A light shape altering device, comprising: a controller, producing information indicative of a plurality of color components for a desired shaped light beam; and a plurality of selectively direction-reflecting devices, respectively receiving said information indicative of said components, each of said selectively direction-reflecting devices selectively passing different light, depending on said color components.
 8. A device as in claim 7, wherein said direction reflecting devices are digital micromirrors.
 9. A device as in claim 7, wherein there are three of said selectively direction-reflecting devices, each of which receives light over a different light path.
 10. A device as in claim 7, further comprising an image memory, storing an image whose contents are used by the controller to produce said plurality of color components.
 11. A mirror gobo, comprising: a light source producing at least two separated color components; at least two electrically pixel-level controllable devices, which are electrically controlled to change position, a first of said devices being optically in series with a first of said color components, and a second of said devices being in series with a second of said color components.
 12. A mirror gobo as in claim 11 further comprising a light splitter for said light source, splitting an output of said light source into multiple color components. 